Hydrostatic transmission

ABSTRACT

An improved compact design for a hydrostatic transmission having a hydraulic pump and hydraulic motor mounted on a center section in a housing, wherein the pump and motor are mounted at generally right angles to one another, and the longitudinal axis of the input shaft is located between a first and second parallel planes located at respective ends of the motor shaft and the longitudinal axis of the motor shaft is located between a third and fourth parallel planes located at respective ends of the pump shaft.

This application is a continuation of U.S. patent application Ser. No. 10/702,333 filed Nov. 6, 2003, which is a continuation of U.S. patent application Ser. No. 10/243,368 filed Sep. 13, 2002, which is continuation of U.S. patent application Ser. No. 09/880,587 (U.S. Pat. No. 6,550,243) filed Jun. 13, 2001, which is a continuation of U.S. patent application Ser. No. 09/846,545, filed on May 1, 2001, which is a continuation of Ser. No. 09/420,183 (U.S. Pat. No. 6,256,988), filed Oct. 18, 1999, which is a continuation of Ser. No. 09/016,584 (U.S. Pat. No. 6,014,861), filed Jan. 30, 1998, which is a continuation of Ser. No. 08/644,474 (U.S. Pat. No. 5,768,892), filed May 10, 1996, which is a continuation of Ser. No. 08/613,371 (U.S. Pat. No. 5,616,092), filed Mar. 11, 1996, which is a continuation of Ser. No. 08/260,807 (U.S. Pat. No. 5,501,640), filed Jun. 16, 1994, which is a continuation of Ser. No. 08/025,272 (U.S. Pat. No. 5,330,394), filed Mar. 2, 1993, which is a division of Ser. No. 07/917,858 (U.S. Pat. No. 5,314,387), filed Jul. 22, 1992, which is a continuation-in-part of Ser. No. 07/727,463 (U.S. Pat. No. 5,201,692), filed Jul. 9, 1991. All of these prior applications are incorporated herein by reference.

BACKGROUND OF THE INVENTION

This invention relates generally to transaxles including a hydrostatic transmission (“HST”) commonly used with riding lawn mowers and similar small tractors. Such tractors generally use an engine having a vertical output shaft which is connected to the transaxle via a conventional belt and pulley system. A standard HST for such a transaxle includes a hydraulic pump, which is driven by the engine output shaft, and a hydraulic motor, both of which are usually mounted on a center section. Rotation of the pump by an input shaft creates an axial motion of the pump pistons. The oil pressure created by this axial motion is channelled via porting to the hydraulic motor, where it is received by the motor pistons, and the axial motion of these pistons against a thrust bearing causes the motor to rotate. The hydraulic motor in turn has an output shaft which drives the vehicle axles through differential gearing.

Among the advantages of transaxles with hydrostatic transmissions are the reduction of the number of parts and in the size of the unit, and, in some instances, the elimination of mechanical gears. As is known in the art, the use of a transaxle having a hydrostatic transmission enables the manufacturer to include all necessary elements in one unit, whereby the transaxle is easily incorporated into the tractor design, as it requires only the addition of a belt to connect it to the motor and a control lever for changing speed and direction. While the basic principles of transaxles with an HST are well known in the prior art, there are several disadvantages of present transaxles with HST designs. These disadvantages, and the present invention's means for overcoming them, are set forth herein.

A major problem with some prior transaxle designs is that the transmission is too large and too expensive to be used with the smaller tractors where it would be most effective. An attempt to solve this problem is shown in Okada, U.S. Pat. Nos. 4,914,907 and 4,932,209. The Okada '209 patent discloses a first mechanical deceleration means, namely the gear on the motor shaft and countershaft within the axle housing, and a second mechanical deceleration means in the differential. The gearing in the deceleration means eventually transmits power to the differential gears, which are then used to drive the output axle. However, these mechanical deceleration units add unnecessary weight and expense to the unit. An object of the present invention is to provide an transaxle design which does not require such additional mechanical deceleration means.

Another variation on the standard transaxle with HST design is shown in Thoma, U.S. Pat. No. 4,979,583. This patent teaches the segregation of the hydraulic units from the remaining portions of the transaxle through the use of separate segregated cavities to house each. In addition, the pump and motor in the Thoma design are mounted back-to-back, so that the input and output shafts have the same orientation. Thus additional gear units are required to re-orient the rotation of the output shaft so that it is parallel to the ultimate drive axle. Further gears then drive a differential which rotates the drive axle. This additional gearing adds weight to the unit and expense to the manufacturing process.

Thus, the Okada and Thoma designs present problems from the standpoint of manufacturing a small, economical transaxle including an HST which is easily adaptable to different size tractors or axle configuration. Okada requires multiple gearing and Thoma requires a housing having segregated cavities. The present invention is designed to overcome these and other problems in the prior art by providing a compact, economical transaxle with HST which substantially reduces the number of moving parts previously required.

SUMMARY OF THE INVENTION

The present invention, sometimes referred to generally as a “transaxle,” includes a split-axle housing which encases an HST. The HST includes a pump and a motor whose orientation to one another may be varied according to the space requirements dictated by the size and configuration of the vehicle. This transaxle also includes a novel hydraulic reduction means, an improved differential, a longer lasting, more effective means of preventing oil leakage from the axle shafts in the housing, a center section supporting the output drive shaft, an improved means for hydraulically bypassing the HST and a unique check valve arrangement. Each of the specific novel improvements are combined to provide a transaxle which is compact, reliable and economical to manufacture. These and other objects and improvements of this invention will be set forth in more detail herein.

One object of this invention is to provide an improved transaxle wherein the center section of the HST, on which the pump and motor are mounted, also serves as the bearing support of the output drive shaft. In the prior art, for example, Okada U.S. Pat. No. 4,932,209, one end of the gear drive arrangement is supported in the center section, but the other end is supported by the upper and lower axle housing casings.

The advantage of the present invention's arrangement is that it eliminates the need for an additional bearing support, thus reducing the costs and assembly time required. It also eliminates the tolerance concerns for aligning the bearing supports for the output drive shaft.

A further object of this invention is to provide a transaxle that may use multiple mechanical reduction units, but requires only a single such unit because a portion of the overall reduction is provided hydrostatically. The prior art generally requires dual or multiple mechanical reduction units in conjunction with the hydraulic unit. For example, as set forth above, U.S. Pat. No. 4,932,209 requires the use of two separate mechanical reduction units, including a separate counter-shaft between the hydraulic motor and the differential used to drive the output axle.

The present invention makes this same reduction through the hydraulics itself by the use of a motor which is larger in displacement than the pump. This eliminates the need for any secondary mechanical reduction units, thereby reducing sources of possible mechanical failure. The single reduction arrangement reduces the number of necessary components and the size of the transmission, and it eliminates the need for an additional support shaft or jack shafts, thus resulting in a smaller, simpler and less expensive transaxle. In a heavy duty application, the prior art often used two sets of mechanical reduction units to handle the necessary reduction. In such instances, the present invention's hydraulic reduction can eliminate the need for such multiple reduction units or could be used in conjunction with secondary units only.

A further object of this invention is to restrict the oil from having to extend to the outer axle support bearings, as is common in prior art models. The gearing and the hydrostatic transmission element of this invention are enclosed in a single chamber formed by an upper casing and a lower casing. The axle shafts extend through this chamber and are supported by separate bearing surfaces outside of the chamber.

In most of the prior art, the entire axle casing is filled with oil out to the outer axle bearings to provide lubrication to these bearings, in addition to the hydrostatic function of the oil in the pump and motor. However, after the outer axle bearings wear through use, the eccentricity or “play” in the shaft may distort the oil seal at said outer bearings, allowing the leakage of oil out of the main chamber. Maintenance of a leak-free joint is critical to the function and appearance of such a transaxle with HST unit. The entire internal hydraulic parts of an HST should be covered with oil, as an insufficient amount of oil in the main transmission cavity will cause foaming of the oil, damaging the hydraulic structures. Excessive oil leakage is a serious problem as it will hamper the ability of the HST to operate and cause damage to the internal workings of the HST. Oil leakage also presents an aesthetic problem for manufacturers of transaxles, as customers are usually quite disturbed by the presence of oil leaks and the accompanying oil stains. Thus, the reduction or elimination of oil leakage is critical for the continued success of transaxle sales.

In the prior art, maintenance of such a leak-free joint at the outer bearings requires the use of extra bolts and sealant, which add additional weight and cost to the unit. An additional problem with prior art designs is that such wear in the outer axle bearings can also cause contamination of the oil due to the presence of “shavings” and other detritus from the worn bearings.

Although such construction could be used with the other novel elements of the present invention, to solve these problems of leakage and potential oil contamination at minimum cost, the present invention also presents a unique means of restricting the oil to those portions of the transaxle where it is needed to lubricate the differential and to work the pump and motor of the HST. Thus, chambers separate from the main chamber enclosing the HST and differential surround the majority of each axle shaft. Therefore, the oil does not extend throughout the entire casing or to the outer axle bearings, removing the potential problem of oil leaking from the casing. Separate grease pockets are used to lubricate these outer axle bearings, resulting in a much more durable seal and allowing for the use of a higher viscosity grease lubricate these outer axle bearings.

This improvement also allows for a reduction in the amount of oil needed to fill the transmission case, and, due to the reduced sealant area at the outer axle bearings, a reduction in the amount of sealant required. Due to the fact that the maintenance of a leak-free joint at the outer axle bearings is not required, this invention also allows for reduced manufacturing tolerances, which reduces the manufacturing costs of the unit.

A further improvement is in the method used to place the transaxle into neutral gear to enable movement of the tractor without the motor running. A problem with the typical HST arrangement is that “neutral gear” does not exist, as it is merely a point where the hydraulic pressure in the pump goes to zero. However, at this point the oil remains in the transmission, preventing the vehicle from being rolled freely.

The prior art generally solves this problem by diverting the oil through a hydraulic valve from the pressure side to the vacuum side of the HST center section. The problem with such a design is that the hydraulic valve allows for the movement of only a limited amount of oil due to inherent design limitations, such as the diameter of the hydraulic value through which the oil is diverted. Furthermore, machining such a valve requires precise tolerances, thus increasing the manufacturing costs of the unit.

In the present invention, this problem is solved by providing a mechanism whereby the motor block is mechanically lifted from its running surface, thereby allowing the oil to bypass the vacuum-pressure circuit and to exit the case completely. This operates to enable the vehicle to freewheel more easily than is possible with the prior art hydraulic valve method.

Another object of the present invention is to provide an improved design of the motor and motor thrust bearing in a hydrostatic transmission, whereby the motor shaft does not extend through the motor thrust bearing, and thus the bearing is fully supported and does not require an intermediate support plate, as is used on prior art models.

For example, U.S. Pat. No. 4,953,426 to Johnson teaches a thrust bearing having a motor shaft extending through its center section. As in the present invention, the thrust bearing in Patent '426 is supported by one section of the housing. However, because the '426 thrust bearing has the motor shaft extending through its center, it is not solely supported by the housing, but rather is supported by two “fingers” on either side of the thrust bearing. To support the thrust bearing against the hydraulic forces applied by the motor pistons, an additional structurally significant piece is required to support between these fingers.

In the present invention, the thrust bearing is fully supported by the housing part into which it is inserted, thus eliminating the need for an additional structural member. This results in an assembly that is simpler and less expensive to manufacture.

A further object of this invention is an improved differential gear assembly. In the prior art, differential assemblies generally require a cross-shaft to support the planet bevel gears. The arrangement of the present invention eliminates the need to use such a cross-shaft by providing a simple end cap axle support and bevel and planet gear entrapment.

A further novel feature of this invention is in the placement of the brake portion in the housing. Disk brakes are known in the art, and generally consist of a series of disks or plates, mounted on or about a rotating shaft, with at least some of the disks or plates rotating with the shaft. Such brakes generally have a brake arm or level which is moved to activate the braking feature by a means for transmitting the movement of the brake arm to the series of disks, causing the stationary disks to be pressed against the rotating disks, thus braking this rotating shaft through friction. This means for transmitting the movement of the brake arm to the disks generally consists of rods or shafts, and, in the prior art, these rods or shafts were mounted in a housing which is separate from the housing containing the HST. In the present invention, the brake rods are mounted directly into the HST housing through half-round sections formed into each of the mating housing sections, thus eliminating the need for this separate housing and reducing the manufacturing costs of the products.

An additional novel feature of this invention is the design of the check valve for the center section. Prior art check valve designs generally use hardened steel balls working against a steel or cast iron seat. To minimize the overall weight of the transaxle unit, however, the center section of the present invention is preferably made of cast aluminum, which is not strong enough to function as such a valve seat and to withstand the wear from such a check valve operation. This problem is solved by the use of a steel insert in the center section to support the steel balls.

To create a seal at such a location, it is known to use a machined surface on both the seat and the insert, so that a standard O-ring seal could be used. However, use of such a sealing means would require additional machining steps on the seat and insert, adding to the overall manufacturing costs of the unit.

To overcome these problems in the prior art, the present invention calls for the use of a powdered metal plate which acts as both the check valve seat and as the seal. The sealing functions of the plate are created through the use of a raised surface on the plate, which is pressed into the lower strength aluminum to form a seal. This design has the advantage of being simple and inexpensive to manufacture, while maintaining the advantage of a light overall weight.

It is a further object of this invention to provide an improved hydrostatic transmission wherein the pump and the motor of the HST need not be orientated at a 90-degree angle to one another as required by the prior art. In the present invention, the 90-degree orientation is the preferred embodiment. However, an orientation other than 90-degrees can be achieved by use of a helical gear between the output drive shaft and the differential.

Further explanation and details of the above objects of this invention, as well as other benefits and advantages of this invention, will be set forth in the following sections.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a top view of a transaxle with a hydrostatic transmission manufactured in accordance with this invention.

FIG. 2 is a fragmentary elevational section view along the line B-B of FIG. 1.

FIG. 3 is a fragmentary side view along the line C-C of FIG. 1.

FIG. 4 is a fragmentary elevational section view along the line A-A of FIG. 1.

FIG. 5 is a perspective view of a center section of a hydrostatic transmission in accordance with this invention.

FIG. 6 is a bottom plan view of a center section of a hydrostatic transmission in accordance with this invention.

FIG. 7 is the top view of the check valve plate for the center section of a hydrostatic transmission.

FIG. 8 is a fragmentary section view along the line D-D of FIG. 7.

FIG. 9 is a detailed view of the motor and motor shaft of the hydrostatic transmission of the present invention.

FIG. 10 is a top view of the endcap of the differential of the present invention.

FIG. 11 is a side view of the endcap of FIG. 10.

FIG. 12 is an end view of the endcap of FIG. 10.

FIG. 13 is a top view of a ring gear used in the differential of the present invention.

FIG. 14 is a top view of one embodiment of the entire differential.

FIG. 15 is a top view of an end cap used in one embodiment of the differential.

FIG. 16 is a sectional view of the end cap used in the differential shown in FIG. 14 the E-E axis in FIG. 15.

FIG. 17 is a side view of the planet gear used in the differential.

FIG. 18 is a side view of the bevel gear used in the differential.

FIG. 19 is a top view of a portion of a transaxle showing the braking mechanism used with this invention.

DETAILED DESCRIPTION OF THE DRAWINGS

All hydrostatic transmissions operate on the principle of an input shaft driving a pump, which, through the action of its pistons, pushes oil to a motor, which rotates a motor shaft. This rotation is eventually transferred through a differential gearing system to drive an axle shaft. With these general principles in mind, we turn to the drawings of the present invention showing the various improvements made by this invention on the prior art.

FIG. 1 shows an overview of the entire transaxle of the present invention including an HST system. Referring also to FIGS. 2 and 3, the transaxle is encased in an upper housing 1 and a lower housing 2 which are secured by a plurality of bolts 145 and a liquid gasket seal 82 at the joining surface of housings 1 and 2. Input shaft 75, which has a longitudinal axis 75A, extends through shaft opening 116 and is supported by bearing 7 and ring 5, which are retained by seal 4. Input shaft 75 is driven by a belt (not shown) which is powered by a vertical shaft engine (not shown). As shown most clearly in FIG. 3, the rotation of input shaft 75 rotates the cylinder block 14 a of pump 14 at the speed of input shaft 75. Pump 14 is of conventional construction, containing a series of piston receiving chambers 146, each of which movably mounts a pump piston 13 and piston spring 12 in a direction axial to cylinder block 14 a of pump 14.

Pump pistons 13 are powered by piston springs 12 against thrust bearing 9, which, as is well known in the art, is rotatably supported in swashplate 10 by a standard bearing and bearing guide structure, including bearing 112. Swashplate 10 is itself supported in upper housing 1 by bearing cradle 8, as shown in FIG. 4.

Thrust bearing 9 acts as a ramp against which pump pistons 13 are pressed. The rotation of pump 14 causes pump pistons 13 to travel up or down this ramp, thus creating an axial motion for pump pistons 13. Swashplate 10 may be moved to a variety of positions on bearing cradle 8 to vary volume of oil pumped, which ultimately varies the speed of motor 27, as described herein.

Movement of swashplate 10 is accomplished by the user's manipulation of trunnion shaft 15, which in turn moves bearing guide 18. As is known in the art, trunnion shaft 15 is supported by journal bearing 17, which is retained by seal 16. For example, if thrust bearing 9 is perpendicular to input shaft 75 and thus perpendicular to the axial plane of pump pistons 13, there will be no point along thrust bearing 9 where pump pistons 13 are forced axially, thus resulting in no axial motion for pump pistons 13 and no oil flow between pump 14 and motor 27. This position is effectively a “neutral” position for the HST, in that rotation of input shaft 75 will not ultimately result in movement of the vehicle.

The operator may move swashplate 10 by adjusting trunnion shaft 15, which varies bearing guide 18, in one direction to create a “forward” ramp at thrust bearing 9, so that axial motion of pump pistons 13 forces the oil flow in one direction. The operator may also reverse the flow by moving thrust bearing 9 to the opposite, or reverse, position. The details, of the resulting oil flow through the porting system of the HST are set forth herein.

FIGS. 5 and 6 show center section 74 of the HST, which is securely mounted to upper housing 1 through bolt openings 103. Pump 14 is rotatably mounted on pump running surface 130 with center opening 138 corresponding to shaft opening 116 to receive input shaft 75.

Motor 27 is rotatably mounted on motor running surface 61 by conventional means and is supported by motor shaft 22. When the HST is not in operation, motor 27 is sealed to motor running surface 61 through the force of motor piston springs 25 against motor pistons 26, which press against thrust bearing 23 to create this seal. When the HST is in operation, there is an additional force resulting from the oil pressure. Specifically, the interior of motor piston chamber 147 is sufficiently large enough that the flow of oil through passage 102 creates a resultant net balance of oil pressure in cylinder block 27 a in the direction towards motor running surface 61, creating a seal at this point. Pump 14 is retained on pump running surface 130 in a similar manner.

Center section 74 includes bearing structures 74A and 74B, which are integrally formed therewith and include bearing openings 88 and 89. Motor shaft 22, which has a longitudinal axis 22A, is installed through and fully supported by openings 88 and 89 and running surface 140. The means of supporting motor shaft 22 is a significant improvement over the prior art, which discloses the motor shaft supported at one end in the center section, and at the other end on some other external bearing housing. The present invention eliminates the need for such an additional bearing housing for motor shaft 22, reducing manufacturing expense and weight, as well as reducing the overall size of the unit.

Proper alignment of motor shaft 22 is critical to the performance of the HST. The design of the present invention eliminates the necessity of aligning such an additional bearing support with the support on center section 74, resulting in an overall savings in weight and expense, as well as increasing the ease of manufacture of the transaxle.

As shown in FIGS. 2 and 3, the longitudinal axis 22A of motor shaft 22 is located between a first plane P1 formed at one end of input shaft 75 and a second plane P2 formed at the opposite end of input shaft 75, where planes P1 and P2 are generally perpendicular to the longitudinal axis 75A of input shaft 75. Similarly, the longitudinal axis 75A of input shaft 75 is located between a third plane P3 and a fourth plane P4, wherein planes P3 and P4 are generally perpendicular to the longitudinal axis 22A of motor shaft 22, and plane P3 is formed at one end of motor shaft 22 and plane P4 is formed parallel to plane P3 and at the opposite end of motor shaft 22. It can also be seen in FIG. 2 that the two ends of motor shaft 22 are on opposite sides of a plane formed by the longitudinal axis 75A of input shaft 75 and perpendicular to longitudinal axis 22A. Similarly, as shown in FIG. 3, the two ends of input shaft 75 are on opposite sides of a plane formed by longitudinal axis 22A of motor shaft 22 and perpendicular to longitudinal axis 75A.

As most clearly shown in FIGS. 2 and 9, motor 27 also contains a plurality of piston chambers 147, each of which contains a motor piston 26 and piston springs 25. Each motor piston chamber 147 has a passage 102 to receive oil flow from arcuate ports 106 and 107 on motor running surface 61 of center section 74.

Each motor piston 26 is driven by the oil flow received through arcuate ports 106 or 107 in a direction axial to motor 27 and against the generally circular motor thrust bearing 23. As shown in FIGS. 3 and 9, motor thrust bearing 23 is fixed in its position relative to motor pistons 26 at an angle such that the action of motor pistons 26 against thrust bearing 23 creates a rotational movement of cylinder block 27 a of motor 27. Motor thrust bearing 23 is of standard construction and is composed of bearing plates 23 a and 23 b and bearing race 23 c. Motor 27 is supported on and drives motor shaft 22. Cylinder block 27 a of motor 27 has internal gear teeth (not shown) which mesh with gear teeth 45 on motor shaft 22 to rotate motor shaft 22 at a speed equal to the rotation of cylinder block 27 a of motor 27.

A major improvement that this invention presents over the prior art is the elimination of the need for an intermediate support for motor thrust bearing 23. As shown in FIGS. 1, 2 and 9, motor shaft 22 does not extend through the center of thrust bearing 23. Therefore, thrust bearing 23 is fully supported at its proper angle by upper housing 1 without the need for an additional structural member such as is used for pump thrust bearing 9, which must be supported by swashplate 10. This results in a less expensive and simpler unit to manufacture, and the absence of the additional member reduces the overall size and weight of the transaxle unit.

As described below, oil flow from pump 14 to motor 27 is the means by which rotational power is transmitted by the HST. Arcuate ports 136 and 137 on pump running surface 130 provide the means for transferring oil from passage 101 of pump piston chamber 146 through oil passages 104 or 105 and to motor 27. Arcuate ports 106 and 107, which are located on motor running surface 61 and which coact with passages 102 of motor piston chamber 147, act to receive the oil from oil passages 104 or 105 and return it to pump 14.

It is to be understood that there are a plurality of pump pistons 13 and motor pistons 26 and their related parts and chambers, and, therefore, the discussion herein of these parts in a singular sense is for convenience only, and should not be read to limit the invention in any way. In the preferred embodiment, there are five (5) pump pistons and seven (7) motor pistons.

As shown in FIG. 3, each pump piston chamber 146 has a passage 101 opening for coaction with arcuate ports 136 and 137 on pump running surface 130 of center section 74. In the “forward” oil flow direction described above, the oil flow created by the movement of pump pistons 13 moves through passage 101 to arcuate port 137, and then through oil passage 105 to arcuate port 106 on motor running surface 61, and finally to passage 102 of motor piston chamber 147. The oil then returns to pump piston chambers 146 through passage 102, arcuate port 107, oil passage 104, arcuate port 136 and passage 101.

In the “reverse” oil flow direction described above, the oil essentially travels in a reverse direction, being forced by pump piston 13 through passage 101 and arcuate port 136 to oil passage 104 and arcuate port 107 and passage 102, and finally to motor piston chamber 147. The oil is then returned to pump 14 through arcuate port 106, oil passage 105 and arcuate port 137. The rotational direction of motor 27 depends upon whether this oil flow is in the “forward” or “reverse” direction, as this rotation, and ultimately the movement of the vehicle, will also be “forward” or “reverse.”

As can be seen in FIG. 2, the transaxle design includes expansion chamber 121 formed by external wall 3 and internal wall 124. Such expansion chambers are well-known in the prior art and are used to provide a space for the oil to expand into during operation of the transaxle. Expansion chamber 121 may be located at different areas along the upper and lower housings 1 and 2, and, in the preferred embodiment, expansion chamber 121 is located along upper housing 1 or lower housing 2 outside differential gear 63.

As shown in FIGS. 1 and 2, braking for the transaxle is accomplished through a braking mechanism 109 located on, and supported by motor shaft 22 and comprising brake stator 57 and brake rotor 58, triggered by brake arm 53 and brake actuator 55. Braking mechanism 109 is located within a cavity 110 which is separated from transmission cavity 48 by a standard seal 31.

The novel brake feature of this HST is clearly shown in FIG. 19. Specifically, FIG. 19 is a cutaway portion of the top view of a portion of the transaxle generally shown in FIG. 1, but including the novel brake feature. The remaining elements of the transaxle shown in FIG. 19 can be the same as those shown in FIG. 1.

Motor shaft 222, which can be identical to motor shaft 22 previously described, has, at one end, gear teeth 223 integrally formed thereon. Brake mechanism 250 includes brake rotors 258, which are rotatably mounted on gear teeth 223 of motor shaft 222 such that brake rotors 258 rotate with motor shaft 222, and brake stators 257, which do not rotate. FIG. 19 shows lower housing 202 of the transaxle, which can otherwise be identical to lower housing 2 previously described. Brake arm 253 is connected to lower housing 202 through bolt 254, washer 255 and nut 256. When the brake mechanism 250 is to be activated, the user moves brake arm 253, which causes pins 259 to move in a lateral direction towards brake stator 257. This movement of pins 259 moves stators 257 into contact with rotors 258, causing contact and friction between stators 257 and rotors 258 and thus effectuating braking. Pins 259 are not mounted in a separate housing but are instead contained and held in mating half-round sections formed into both lower housing 202 and the upper housing (not shown) of transaxle. The advantage this design presents is the elimination of separate housing elements for the pins, reducing the weight and cost of the unit.

As is known in the prior art, the present invention uses a differential to transfer power from motor shaft 22 to the pair of oppositely-extending axle shafts 62 and 62′ which are used to drive the vehicle. As shown in FIGS. 1-3, motor shaft 22 contains a center portion 46 which contains gear teeth 126 which mesh with teeth 63 b on differential gear 63. Differential gear assemblies known in the art generally include an internal cross-shaft that serves as the actual driving mechanism for the output axles. A key improvement in this invention is the use of a novel structure which eliminates the need for such an internal cross shaft on differential gear 63.

As shown in FIG. 1, the various differential gears are contained in differential housing 64, which includes two identical opposing endcaps 108 and 108′. Endcaps 108 and 108′ are shown in detail in FIGS. 10, 11 and 12. Axle shaft opening 152 is integrally formed therein to receive axle shaft 62 or 62′. Bolt openings 154 and 154′ are also formed therein to receive and secure bolts 68 and 68′.

As is shown most clearly in FIG. 3, planet gear 66 is mounted onto the inside of differential gear 63 through opening 63 c by means of a key or raised portion 66 a which fits into keyway 63 a formed in differential gear 63. Planet gear 66′ is similarly located. Planet gears 66 and 66′ are thus held in place by keyways 63 a and 63 a′ and endcaps 108 and 108′. This arrangement replaces the cross-shaft of prior art designs, where the cross-shaft was used to support the planet gears.

Planet gears 66 and 66′ include a plurality of teeth 66 b and 66 b′, which are meshed with and cause the rotation of bevel gears 65 and 65′. Bevel gears 65 and 65′ are meshed with respective axle shaft gears 47 and 47′ to cause rotation of axle shafts 62 and 62′.

Thus, each bevel gear 65 and 65′ is located and held in place by planet gears 66 and 66′ on one side and by endcap 108 or 108′ on the other side. Endcaps 108 and 108′ function to center and hold bevel gears 65 and 65′ and to allow the entire differential assembly to be held together by two bolts and nut assemblies 68 and 68′. This is a much more compact and less complicated design than has been used in the prior art. In addition, the elimination of a cross shaft removes the need for a hollow center section, thereby making the differential design of the present invention stronger than prior art models.

Another embodiment of this differential is shown in FIGS. 13-18, wherein planet gears 266 are secured by and mounted on end caps 208. Specifically, as shown in FIG. 17, each planet gear 266 has a tab 267 which may be integrally formed therewith, and tab 267 is mounted for rotation on curved mounting surface 215 on end cap 208. When two end caps 208 and 208′ are mounted together as shown in FIG. 14, their respective mounting surfaces 215 combine to secure planet gears 266 in place.

Each end cap 208 has a notch 220 which may be integrally formed therein and which fits into keyway 268 formed into ring gear 263. As ring gear 263 rotates, force is transmitted from the sides of keyway 268 to notch 220 of end cap 208, causing the entire differential unit 200 to rotate. Thus each end cap 208 receives the rotational force of ring gear 263 through notch 220 and transmits that force to planet gear 266, causing planet gears 266 to move with the rotation of ring gear 263.

As shown in FIG. 14, the differential unit 200 is secured together through the use of a pair of bolts 275 and 275′ mounted through and securing end caps 208 and 208′. Each planet gear 266 engages and drives bevel gears 265 to cause the rotation of bevel gears 265 about the same axis of rotation as ring gear 263. At the same time, each bevel gear 265 engages and drives a rotatable output shaft 262 to power the vehicle in which the differential is used. Each bevel gear 265 has an opening (not shown) which corresponds to opening 271 on end cap 208, and which has gear teeth (not shown) to engage and drive an output shaft 262, which has gear teeth 280 formed thereon. Bevel gears 265 are engaged on the inside of differential unit 200 by planet gears 266, and are engaged at their outside surface 269 by mounting surface 270 on end cap 208. Each end cap 200 has a shaft opening 271 which corresponds to bevel gear opening 302 to receive output shaft 302.

As discussed above, end caps 208 and 208′ may be bolted to one another using bolts 275 and 275′ through bolt holes 301 to form a single differential unit. It is also possible to use one larger end cap in place of the two separate end caps. In such embodiment the one large cap unit is bolted to an outside face of ring gear 263 and holds and rotatably mounts both planet gears 266.

The embodiment shown in FIGS. 13-18 shows the differential unit being mounted within the center, i.e., between the outside faces of ring gear 263. However, it is also possible for the planet gears 266, bevel gears 265, and end caps 208 to be mounted off-center, such as on the outside face of ring gear 263, with rotational force still being transferred from ring gear 263 to planet gears 266 through the single end cap unit secured to ring gear 263 or through a set of end caps similar to those described above.

As shown in FIGS. 3, 7 and 8, center section 74 contains a check valve mechanism including check valve plate 41, ball 39 and spring 40. Plate 41 is formed of powdered metal which is significantly harder than the cast aluminum used to form center section 74. Bottom face 79 of center section 74 is shown in FIG. 6. Plate 41 is mounted on bottom face 79 by three bolts 42 through bolt openings 127 and received by openings 128 on bottom face 79 of center section 74.

Plate 41 has top surface 148, which is flush with bottom face 79 of center section 74 when mounted, and bottom surface 149. As shown in FIG. 8, bottom plate surface 149 has generally circular opening 133 formed therein, while top plate surface 148 has a slightly larger opening 131 formed therein. Openings 133 and 131 coact with each other and with valve openings 156 on bottom face 79 to form check valve 139. Check valve 139 includes ball support surface 135 to support ball 39 when check valve 139 is in the closed position, as shown in FIG. 3. When the check valve 139 is opened, ball 39 lifts off of ball support surface 135 to allow oil from sump 155 to flow through check valve 139. Oil filters 43 are used to prevent contaminants from entering sump 155 from transmission cavity 48.

A raised annular surface or ring 129 is formed around opening 133 on top surface 148 of plate 41, and is pressed into the lower strength bottom face 79 of center section 74 to form a seal between plate 41 and center section 74. The minimal leakage which may occur due to deflection in the metal does not affect operation of the transaxle because center section 74 is within main transmission cavity 48, which is filled with oil. Thus, the present invention provides a simple, low cost sealing mechanism which allows for the use of a lighter cast aluminum center section without the need for the use of additional machining to use an O-ring, as is done in the prior art.

Prior art HST designs have the pump and motor mounted either at a 90-degree angle or in a parallel arrangement, whereby the pump and motor are set “back-to-back.” In the present invention, the preferred embodiment calls for these elements to be positioned on center section 74 at the standard 90-degree angle to one another, as shown in the drawings. However, if necessary, center section 74 could provide for motor running surface 61 to be inclined upwardly or downwardly in the vertical plane of FIG. 2. Such an orientation, which may be required by the configuration of the vehicle, would also require motor shaft 22 to remain parallel to motor 27. In this position, motor shaft 22 is no longer perpendicular to axle shafts 62 and 62′ and differential gear 63, as is required to have gear teeth 63 b and gear teeth 126 of motor shaft 22 to mesh using standard gearing.

To allow such an arrangement, the present invention would require the use of a helical gear at motor shaft center portion 46 or on differential gear 63 to allow these gears to properly mesh. Such helical gears are well-known in the art, but have not previously been used in HST designs to allow the pump and motor to be oriented at angles other than the standard 90-degrees. The angle of the helix on such a gear is determined by the angle between the motor shaft 22 and the axle shafts 62 and 62′.

With a transaxle, it is necessary to reduce the rotational speed of the input shaft as it is transmitted to the final drive axles. One of the disadvantages of prior art transaxle designs is the need to provide a reduction of angular shaft speed through mechanical gearing. Such mechanical reduction requires the use of extra gears, shafts, supports and various other related parts, as shown in prior art patents. This results in additional expense in manufacturing as well as additional weight in the transaxle. Furthermore, mechanical gears are subject to failure if stressed sufficiently or repeatedly.

In the present invention, at least a portion of this shaft speed reduction is accomplished through the hydraulics. In a preferred embodiment, this is accomplished by internally sizing motor 27 at a larger capacity than pump 14. As an example of the preferred embodiment, it has been discovered that if the capacity of motor 27 is 21 cubic centimeters (cc), while the capacity of pump 14 is 10 cc, a significant reduction in the speed of motor shaft 22 is achieved. With such sizing it has been found that the angular speed of motor shaft 22 is generally reduced to about one-half of the angular speed of input shaft 75.

In light duty applications where the prior art would require a double mechanical reduction, the present invention can eliminate this secondary mechanical reduction altogether. In heavy-duty applications which would require two or three mechanical reduction units, the present invention may only require a single secondary mechanical reduction unit. In either event, the present invention results in a significant savings in size, weight and expense over prior art designs. This also results in an improvement in reliability, as a hydraulic reduction is less susceptible to breakdown due to the fewer number of moving parts required. Furthermore, a hydraulic reduction is less likely to break from being overstressed than is a mechanical gear reduction.

As seen in FIG. 1, axle shafts 62 and 62′ extend from differential housing 64 through transmission cavity 48 and axle cavity 49 to outer axle bearings 72. The wheels (not shown) of the vehicle are then attached at axle ends 150 and 150′. In prior art models, oil extends throughout axle cavity 49 along the length of the axle shafts to lubricate outer axle bearings 72 and is sealed in cavity 49 at seal 120.

However, inherent in the manufacture of any such axle shaft is a slight deviation from the main axis at either end 150 or 150′ of axle shafts 62 and 62′. Such minor deviations occur through imperfections in the manufacturing process and do not affect performance of the axle shaft or the transaxle. Further deflection occurs due to axle loading at ends 150 and 150′. The sum of these deflections together with any wear at the outer axle bearings 72 can create minor gaps at seal 120, which can cause leakage of oil from axle cavity 49. Such a gap at seal 120, and subsequent oil leakage, can also occur through normal wear and tear. Wear of seal 120 and outer axle bearings 72 can cause detritus from the seal, bearing and surrounding structures to contaminate the oil.

In the prior art, oil leakage has been dealt with through the use of extra bolts and sealant at the location of seal 120 as well as at additional locations along sealing surface 125. This results in additional parts, expense and weight for the unit.

Since the present invention does not fill axle cavity 49 with oil, this problem is eliminated without the need for such extra bolts or sealant. As shown in FIG. 1, seals 71 are used to prevent oil from flowing from transmission cavity 48 to axle cavity 49. Seal 71 thus operates as the primary oil seal for transmission cavity 48 and, in a preferred embodiment, seal 71 is a seal made of nitryl.

In the present invention, a conventional higher viscosity grease within axle cavity 49 provides the necessary lubrication to outer axle bearings 72. Use of this higher viscosity grease provides better lubrication to the outer axle bearings 72 than is available through the use of oil. Seals 120 serve to maintain this higher viscosity grease within axle cavity 49 and thus do not serve as the primary oil seal. Moving the primary oil seal from outer axle bearing 72 to seal 71 eliminates or minimizes oil leaks, extends the life of the product and reduces the quantity of oil needed in the casing. Seals 120 further act to minimize the amount of outside contaminants which reach outer axle bearings 72.

Another important and novel feature of this invention is the hydraulic bypass shown in FIGS. 2 and 9. The effect of this bypass system is to enable the vehicle user to roll or “freewheel” the vehicle without resistance from the oil in the HST. When an HST does not have any power being applied to it through the tractor motor, pump 14 and motor 27 are not being rotated. Therefore, any attempt to roll the vehicle would transmit the rotational energy through axle shafts 62 and 62′, and through differential gear 63 to motor shaft 22. This in turn will rotate motor 27, and the action of motor pistons 26 against motor thrust bearing 23 causes axial motion of motor pistons 26, causing oil flow through the porting of center section 74. However, with pump 14 at neutral there is no place for the oil to go, and high pressure results. This high pressure causes resistance to further motion of motor shaft 22 and axles 62 and 62′ and prevents the user from pushing the tractor.

Prior art solutions to this problem generally involve placing a valve between arcuate ports 106 and 107 to allow the oil to flow between these two ports, i.e., between the pressure side and vacuum side of HST center section 74. However, such a hydraulic valve allows only a limited amount of oil to pass between the ports due to inherent design limitations, such as the diameter of the hydraulic valve through which the oil is diverted. Such a valve also requires accurate machining to maintain minimum clearances to reduce leakage during normal operation of the unit.

The present invention solves this problem by use of a mechanism to lift motor 27 off of motor running surface 61 of center section 74, thus breaking the seal at that point and allowing oil to flow out of arcuate oil port 106 and into transmission cavity 48. Thus, the oil is not ported from the pressure side to the vacuum side, but rather bypasses this entire circuit within center section 74.

To activate this feature, bypass arm 50 is manipulated by the user to rotate bypass actuator 29. Seal 28 is used to retain oil within the main transmission cavity 48 at this point. Bypass actuator 29 includes rod 115, which is shaped at its base so that rotation of rod 115 forces bypass plate 30 to press against the base of motor 27, breaking its seal to motor running surface 61. This allows the oil to flow from arcuate port 106 to transmission cavity 48. The oil is then returned to motor 27 through arcuate port 107. This design enables the vehicle to readily “free wheel” with less resistance from the oil.

Further manipulation of bypass arm 50 and rod 115 causes bypass plate 30 to withdraw off of motor 27, allowing motor 27 to return to its normal position on motor running surface 61, reestablishing the seal at that point. The design of the present invention could also be used in a different embodiment to lift pump 14 off of pump running surface 130, as this would have the same effect.

An advantage of this design is that it is very simple and inexpensive to manufacture and install because it does not require precise tolerances. Prior art hydraulic bypasses using valves to move the oil between its porting sections require very precise machining of the valves to prevent unwanted leakage, and are therefore more expensive to manufacture. In addition, this mechanism dissipates the oil into the cavity rapidly to allow immediate movement of the vehicle.

The above descriptions are intended to illustrate the various features of this invention and are not intended to limit it in any way. Further advantages will be obvious to one of ordinary skill in the art. This invention should be read as limited only by the following claims. 

1. A center section for a hydraulic drive apparatus having a sump, the center section comprising: a first running surface comprising a first pair of arcuate ports; a second running surface formed perpendicular to the first running surface and comprising a second pair of arcuate ports; first and second system ports formed in the center section, wherein the first system port extends from one of the second pair of arcuate ports at an oblique angle to the second running surface, and wherein at least a portion of both the first and second system ports pass below the first running surface; a first check valve located in the center section between the first system port and the sump; and a second check valve located in the center section between the second system port and the sump.
 2. A center section as set forth in claim 1, wherein the second system port extends from the other of the second pair of arcuate ports at an oblique angle to the second running surface.
 3. A center section as set forth in claim 1, wherein the first system port terminates at one end thereof within the body of the center section generally adjacent to one of the first pair of arcuate ports, and the second system port terminates at one end thereof within the body of the center section adjacent to other of the first pair of arcuate ports.
 4. A center section as set forth in claim 1, wherein the first and second check valves each comprise a check valve opening formed in an external surface located on a side of the center section opposite to the first running surface.
 5. A center section as set forth in claim 3, wherein the opposite end of the first system port terminates at one of the second pair of arcuate ports.
 6. A center section as set forth in claim 5, wherein the opposite end of the second system port terminates at the other of the second pair of arcuate ports.
 7. A center section as set forth in claim 6, wherein both of the first and second system ports extend from the second pair of arcuate ports at an oblique angle to the second running surface.
 8. A center section as set forth in claim 1, wherein at least a portion of the first system port extends in the center section parallel to the plane of the first running surface.
 9. A center section as set forth in claim 8, wherein at least a portion of the second system port extends in the center section parallel to the plane of the first running surface.
 10. A center section as set forth in claim 9, wherein the second system port extends from the other of the second pair of arcuate ports at an oblique angle to the second running surface.
 11. A center section as set forth in claim 10, wherein the first system port terminates at one end thereof within the body of the center section generally adjacent to one of the first pair of arcuate ports, and the second system port terminates at one end thereof within the body of the center section adjacent to other of the first pair of arcuate ports.
 12. A center section as set forth in claim 1, whereby a line extending perpendicular to the second running surface and through the other of the second pair of arcuate ports intersects the first system port.
 13. A center section as set forth in claim 12, wherein at least a portion of the first system port extends in the center section parallel to the plane of the first running surface.
 14. A center section as set forth in claim 12, wherein the second system port extends from the other of the second pair of arcuate ports at an oblique angle to the second running surface.
 15. A center section as set forth in claim 12, wherein the first system port terminates at one end thereof within the body of the center section generally adjacent to one of the first pair of arcuate ports, and the second system port terminates at one end thereof within the body of the center section adjacent to other of the first pair of arcuate ports.
 16. A center section as set forth in claim 12, wherein the first and second check valves each comprise a check valve opening formed in an external surface located on opposite side of the center section to the first running surface.
 17. A hydraulic drive apparatus, comprising: a housing forming a sump and having a center section mounted therein; a pump input shaft extending into the housing and drivingly engaging a rotatable pump cylinder block mounted on the center section; a rotatable motor cylinder block mounted on the center section and driving a motor output shaft; the center section comprising: a pump running surface having a first pair of arcuate ports formed thereon for hydraulically connecting the pump cylinder block to the center section; a motor running surface formed perpendicular to the pump running surface and having a second pair of arcuate ports formed thereon for hydraulically connecting the motor cylinder block to the center section; a first system port connecting one of the first pair of arcuate ports to one of the second pair of arcuate ports and a second system port connecting the other of the first pair of arcuate ports to the other of the second pair of arcuate ports, wherein at least one of the system ports extends away from the motor running surface at an angle oblique to the axis of rotation of the motor output shaft, and wherein both system ports are located in the center section below the plane of the pump running surface; a first check valve located in the center section between the first system port and the sump; and a second check valve located in the center section between the second system port and the sump.
 18. A hydraulic drive apparatus as set forth in claim 17, wherein both of the system ports extend away from the motor running surface at an angle oblique to the axis of rotation of the motor output shaft.
 19. A center section, comprising: a first running surface comprising a first pair of arcuate ports; a second running surface perpendicular to the first running surface comprising a second pair of arcuate ports; a first system port having a first end terminating within the body of the center section and being hydraulically connected to one of the first pair of arcuate ports, and a second end terminating at, and hydraulically connected to, one of the second pair of arcuate ports; and a second system port having a first end hydraulically connected to the other of the first pair of arcuate ports and a second end terminating at, and hydraulically connected to, the other of the second pair of arcuate ports.
 20. A center section as set forth in claim 19, wherein the first system port extends from the one of the second pair of arcuate ports at an oblique angle with respect to the second running surface.
 21. A center section as set forth in claim 20, wherein the first end of the second system port terminates within the body of the center section, and the second system port extends from the other of the second pair of arcuate ports at an oblique angle with respect to the second running surface.
 22. A center section as set forth in claim 20, further comprising a first check valve open to the first system port and located in a first check valve opening formed in an external surface of the center section opposite to the first running surface.
 23. A center section as set forth in claim 22, further comprising a second check valve open to the second system port and located in a second check valve opening formed parallel to the first check valve opening.
 24. A center section as set forth in claim 19, further comprising a pair of check valves formed in the center section and open to the first and second system ports.
 25. A center section as set forth in claim 19, wherein one end of the second system port terminates within the body of the center section.
 26. A center section for a hydraulic drive apparatus, comprising: a first running surface for mounting a rotatable pump cylinder block; a second running surface formed perpendicular to the first running surface for mounting a rotatable motor cylinder block; and hydraulic porting formed in the center section comprising a first pair of arcuate ports formed on the pump running surface; a second pair of arcuate ports formed on the motor running surface; a first system port connecting one of the first pair of arcuate ports to one of the second pair of arcuate ports, wherein one end of the first system port terminates within the body of the center section; and a second system port connecting the other of the first pair of arcuate ports to the other of the second pair of arcuate ports.
 27. A center section as set forth in claim 26, wherein one end of the second system port terminates within the body of the center section.
 28. A center section as set forth in claim 27, wherein the other end of first system port intersects one of the second pair of arcuate ports at an oblique angle with respect to the motor running surface, and the other end of second system port intersects the other of the second pair of arcuate ports at an oblique angle with respect to the motor running surface.
 29. A center section as set forth in claim 27, further comprising a first check valve open to the first system port and a second check valve open to the second system port, each check valve comprising a check valve opening formed on an external surface of the center section opposite to the pump running surface. 